DE102022102705A1 - Collecting device for a reaction vessel unit and reaction vessel unit - Google Patents

Abstract

The invention relates to a collecting device (30) for a reaction vessel unit (21), which has a plurality of reaction vessels (37), the reaction vessels (37) each having an opening (38) which lies in a common opening plane (39), the collecting device (30) has a collecting plate (31), which is designed in such a way that it can be or is arranged in a centrifuge (1) opposite the openings (38) of the reaction vessels (37), and is designed in such a way that during centrifugation it Reaction vessel unit (21) rotates and is collected from the reaction vessels (37) escaping liquid due to the centrifugal acceleration of the collecting plate (31).

Description

The present invention includes a collecting device for a reaction vessel unit and a reaction vessel unit.

It is known that reaction vessel units which have a plurality of reaction vessels, such as microtiter plates (MTP, well plates) with their wells, are cleaned by centrifugation. The MTPs are held on a rotor in a rotor chamber of a centrifuge in such a way that the openings of the reaction vessels point away from an axis of rotation of the rotor, and are centrifuged at a speed of up to a few 1000 rpm.

During centrifugation, the centrifuged contents of the reaction vessels are caught by a wall of the rotor chamber. Substances remaining on the walls and surfaces of the rotor chamber partly flow off and collect in the lower area, but they can also drip down from above and thereby also get into an MTP located in the rotor chamber. If several MTPs are cleaned one after the other in the centrifuge, there is also a risk of cross-contamination, with centrifugate from one MTP dripping into another MTP.

The rotation of the rotor creates air vortices in every centrifuge. If liquid contents are ejected from the reaction vessels during rotation, these air vortices cause aerosols to form. These are also causes of cross-contamination. In genomic applications (typically amplification-based such as PCR), the aerosols are therefore the driving force for contamination.

It has also been shown that MTPs cleaned in the centrifuge can still be wetted on the surface even when the wells are completely empty. This can make further use more difficult, for example if the MTPs are then sealed with a film. The foil is typically glued on to cover the openings of the wells. This can be for sterile interim storage of the MTPs before further use or after filling with a test liquid to isolate the test regime. However, the wetted surface makes it difficult to stick a film on the MTPs.

From the DE 10 2017 113 583 A1 a centrifuge is known in which the housing has a discharge chute below the rotor and the inner surfaces of the housing adjacent to the chute form a funnel which opens into the chute. As a result, the centrifugate that accumulates in the rotor chamber can be collected and discharged better.

From the as yet unpublished at the time of this application DE 10 2021 124 023.9 it is known to supply a cleaning solution to the rotor space in such a way that the cleaning solution is distributed in the rotor space by turning the rotor. Remains of the centrifugate can thus be removed from the walls and surfaces of the rotor chamber by regular frequent rinsing with cleaning agents.

For reasons of hygiene, comparatively frequent cleaning cycles are required, which leads to idle times and high operating costs. This procedure will be unavoidable, particularly for diagnostic applications.

One object of the invention is to reduce or reliably prevent the risk of contamination of a reaction vessel unit in a centrifuge.

A further object of the invention is to minimize or reliably prevent the wetting of a reaction vessel unit in a centrifuge.

A further object of the invention is to minimize the residence time for aerosols in the centrifuge or to prevent the occurrence of aerosols.

A further object of the invention is to minimize the internal surfaces in the housing which can come into contact with the ejected liquid.

A further object of the invention is to minimize the volume of space in which liquid particles can penetrate.

Another object of the invention is to reduce or eliminate the effort involved in cleaning the rotor chamber of a centrifuge for MTP.

A further object of the invention is to keep ejected fluid from all elements of the device, such as the housing, the rotor and the rotor axis, so that these parts do not corrode or are exposed to other chemical interactions with the ejected fluid to, among other things, reduce costs that caused by surface treatments of the elements of the chemical protection device, and to speed up and simplify the manufacturing process.

One or more of the objects is solved by the subject matter of the independent claims. Advantageous developments are specified in the respective dependent claims.

According to a first aspect of the invention, a collecting device is proposed for a reaction vessel unit which has a plurality of reaction vessels, the reaction vessels each having an opening which lies in a common opening plane. The collecting device has a collecting plate which is designed in such a way that it can be arranged or is arranged opposite the openings of the reaction vessels in a centrifuge, and is designed in such a way that it rotates with the reaction vessel unit during centrifugation and liquid exiting from the reaction vessels due to the centrifugal acceleration of the collecting plate is collected.

In the context of the invention, a collecting plate is a structure which has a surface opposite the opening plane of the reaction vessels. Liquid thrown out of the reaction vessels by centrifugal acceleration can be caught on the surface and flow along under the effect of the centrifugal acceleration. In the simplest case, the collecting plate can be flat or essentially flat, arranged parallel to the plane of the opening and open at the edge, in particular the flanks. The collecting surface is preferably non-rotatably connected to the unit, which comprises the rotor and the reaction vessel unit, and thus rotates at the same rotational speed as the rotor. Since flank-side edges of the collector plate are radially furthest from the axis of rotation, the collected liquid is driven due to centrifugal acceleration from the center to the flank-side edges of the collector plate and from there into the rotor chamber.

Ends of the rotor and thus also of the reaction vessel unit arranged on it and of the collecting device, which are opposite one another in the axial direction of the axis of rotation, are referred to as end faces in the context of the application, while those ends of the rotor and the reaction vessel unit arranged thereon as well as the collecting device that are transverse to the axis of rotation opposite each other, are referred to as flank sides or long sides in the context of the application. In use, the faces are transverse to the axis of the rotor and the flanks or longitudinal sides are parallel to the axis of the rotor.

In modifications, the collecting plate can also be curved or kinked or inclined, as long as the collected liquid is guided away from an area that lies opposite the opening plane of the reaction vessels. The liquid discharged from the catcher can be caught on the walls of the rotor chamber. Since the catch plate is arranged opposite the openings of the reaction vessels, the catch plate can also catch liquid dripping from a wall, in particular an upper wall, of the rotor chamber and prevent the reaction vessel unit from being contaminated by the liquid. Even if a plurality of reaction vessel units are cleaned one after the other, cross-contamination can be prevented effectively and easily in this way. The collection device can be used again after cleaning. The collecting device can be made of plastic or metal, for example. For example, chemicals which decompose or deactivate organic molecules can be used for cleaning, provided that the material of the collecting device is resistant to the chemical. An autoclave can also be used for cleaning, provided that the material of the collector is resistant to the temperatures used.

The collecting plate can be arranged or arranged obliquely with respect to the opening plane, so that collected liquid due to the centrifugal acceleration in the centrifuge is discharged along the obliquely arranged collecting plate in the axial direction of a rotation axis of a rotor of the centrifuge. The axial direction refers to an axis of rotation of a rotor of the centrifuge. In the context of the invention, oblique means that a height or a distance of the collecting plate varies with respect to the opening level of the reaction vessels. The slope can be continuous or discontinuous (kinked), constant (straight), or variable over length (curved). It can run from one end face of the collection device or the reaction vessel unit to the other end face (on one side) or from the middle to both end faces (both sides). Since the opening plane of the reaction vessels generally runs parallel to the axis of rotation when the reaction vessel unit is accommodated in the centrifuge, the slope also runs at an angle to the axis of rotation. Since the collecting plate is designed obliquely in the axial direction relative to the opening plane or the axis of rotation, the collected liquid is driven by the centrifugal acceleration along the incline to an end face of the rotor or the rotor chamber, where it can be collected or thrown out. The wall of the rotor chamber, which surrounds the rotor, is less wetted, so the risk of cross-contamination can be further reduced.

The collecting device can have a suction means which is arranged and designed on the collecting plate in such a way that it can suck up the collected liquid.

Such an absorbent can be, for example, a porous material such as a cellulosic layer and/or an open-cell foam. The liquid emptied from the reaction vessels during centrifugation can be taken up by the suction means, so that it cannot flow back or drip back into the reaction vessels. The centrifugation forces the liquid into the suction means and keeps it there by the capillary action thereof.

Such a collecting device is particularly suitable for centrifuges which are not intended for cleaning reaction vessel units and whose rotor chamber is, for example, difficult to access and therefore correspondingly expensive to clean.

The collecting device can have flanks which are preferably arranged circumferentially along the end faces and flank sides, so that the collecting device forms a type of trough in which the liquid emptied from the reaction vessels during centrifugation is received.

If the space above the reaction vessel unit within the collecting device is completely closed, the rotor chamber will not come into contact with liquid and contamination in this regard is ruled out.

It should be noted that the derivation in the axial direction does not exclude a superimposed movement of the liquid transverse to the axis of rotation. In other words, the total draining movement of the liquid at the catcher plate is a combination of the axial draining and the cross-axis draining. It can therefore be advantageous if flanks of the catcher that run laterally along the axis of rotation are pulled downwards from the catcher plate in order to form an obstacle to movement of the liquid transversely to the axis of rotation. A collection of the collected liquid at an axial end can thus be promoted in that the liquid drained transversely to the axis is also drained axially at the flanks drawn downwards. As a result, the concentration of the liquids at one end can be further improved.

In particular, flanks and end faces of the collecting device can be designed to end with an edge of the reaction vessel unit. In other words, when the reaction vessel unit with the collecting device is placed on the rotor of the centrifuge, a closed collecting space isolated from the rotor chamber can be created with the collecting device designed in this way. The rotor chamber is hardly or not at all wetted, so the effort involved in cleaning the rotor chamber of a centrifuge for a reaction vessel unit can be reduced or minimized. Since the collecting device also rotates, the air in the rotor chamber is not or hardly turbulently turbulent, which means that wetting of the surfaces of the reaction vessel units during centrifugation can be avoided. If there is little or no eddy formation, the formation of aerosols in the collection space is reduced or avoided altogether.

At least one discharge opening can be formed on an end face towards which the collecting plate rises. The discharge opening is preferably flush or essentially flush with the inside of the collecting plate. Any liquid that is collected and drained is pushed outwards and can be collected at the front or drained further. Since the outer (flank-side) ends are radially further outward than the center of the end face during centrifugation, the liquid will preferably collect there, so that it can be discharged best there. It is therefore advantageous if two discharge openings are each provided on the outer (flank-side) ends of the end face. The discharge opening can be formed on the front side, ie axially, or on the flank side, ie transversely to the axis. In principle, an upward opening is also conceivable, but means would then have to be provided to prevent dripping back from above and to avoid contamination.

The discharge opening can have a grommet that protrudes beyond the end face. Such a spout moves on a circular path during centrifugation. Collected and discharged substance is expelled outwards and can be discharged via the spout into an annular collection channel in which the spout runs. Contamination of the rotor chamber can be avoided even better, cleaning effort can be further reduced. As stated above, it is advantageous if two discharge openings are provided, each with such a spout.

In embodiments, the collecting device can be placed loosely, preferably in a form-fitting manner, on the reaction vessel unit. The collecting device can be provided separately from the centrifuge. The reaction vessel unit can be prepared for centrifugation outside of the centrifuge with the collection device.

In further embodiments, the collecting device with the reaction vessel unit can be dissolved in be connectable. Here, too, the collecting device can be provided separately from the centrifuge. The reaction vessel unit can be prepared with the collection device for centrifugation so that it cannot be lost. The connection can be, for example, a clip connection, a plug connection, a snap connection, a sliding connection.

In other embodiments, the collecting device can be detachably connectable to a rotor of a centrifuge. In this way, the rotor can be prepared to receive a reaction vessel unit. The collection device can be removed for cleaning and can then be used again. The rotor can also be advantageously cleaned with the collecting device removed.

In further embodiments, the collecting device can be designed to be integrated with a rotor of a centrifuge. Here the rotor is ready to receive a reaction vessel unit without any further preparation, work steps in the laboratory can be simplified. The cleaning of the collecting device and/or the rotor chamber can be carried out together or separately by rinsing in the centrifuge or externally.

The collecting device can also be designed in several parts for easy removal and cleaning.

In still other embodiments, the collector may be connected or connectable to a rotor shaft of a centrifuge. The connection can be made, for example, by a cage or fork body or bracket that can be mounted or flanged in the centrifuge (on the rotor shaft) and holds the collecting device, or the collecting device itself has an extension arm that can be mounted non-rotatably on the rotor shaft. Here, too, the rotor is ready for receiving a reaction vessel unit without further preparation, and there is no need to handle the cover on the reaction vessel unit or on the rotor. Rotor and collector can be cleaned separately. Work steps in the laboratory can be simplified. Cleaning can be carried out by rinsing in the centrifuge or externally (after disassembly from the rotor shaft).

The collecting device can be designed with a circumferential contour which is adapted to the shape of a corresponding reaction vessel unit, so that the collecting device can preferably be placed on the reaction vessel unit in a form-fitting manner and in particular circumferentially in a form-fitting manner. This creates an essentially closed collection space which is optionally only opened by means of the discharge opening, so that when the centrifuge is rotated, the atmosphere contained therein is completely entrained and there are no turbulences that cause aerosol formation.

The collecting device can have a contact contour in order to contact a reaction vessel unit, which has a corresponding complementary contour, the contact contour and the complementary contour being designed in such a way that the collecting device can only be arranged in a single or unique position on the reaction vessel unit, so that the combination consisting of a reaction vessel unit and a collecting device can be arranged in a centrifuge.

The contact contour and the complementary contour can thus be put together according to the key/lock principle. In this way it can be ensured that the collecting device can only be arranged in a specific position with respect to the reaction vessel unit in order to prevent it from being placed incorrectly. The contact contour and the complementary contour can be designed in such a way that if the collecting device is not correctly arranged on the reaction vessel unit, the collecting device protrudes further upwards on the reaction vessel unit, so that the combination of reaction vessel unit and collecting device cannot, for example, pass through an opening in the centrifuge or into a catch area of the rotor of the centrifuge fits. This ensures that the collecting device is not inserted and rotated in a centrifuge with an incorrect arrangement on the reaction vessel unit.

According to a further aspect of the invention, a corresponding reaction vessel unit is provided which has such a complementary contour that is designed to match the contact contour.

The complementary contour and the contact contour can be formed, for example, in a wavy, zigzag shape or from pins and corresponding receiving holes. However, any other desired contours are possible which bring about an unambiguous assignment.

The reaction vessel unit can also have an asymmetrical insertion contour which is positively adapted to a corresponding receiving contour of a rotor of a centrifuge in such a way that the reaction vessel unit can only be arranged in a single position in the rotor.

Such an asymmetrical insertion contour is, for example, webs which protrude laterally along the flanks of the reaction vessel unit without engaging in a corresponding groove of the rotor. This ensures that the React tion vessel unit is only inserted in a unique position in the rotor. This in turn corresponds to the key/lock principle.

Such a configuration of the reaction vessel unit is particularly advantageous in combination with the contact contour of the collecting device explained above and the corresponding complementary contour of the reaction vessel unit as well as the discharge opening of the collecting device, because this ensures that the discharge opening is always arranged on the correct side of the rotor on which the Centrifuge is designed accordingly for draining the liquid.

Furthermore, the collecting device can have projections in the area of a contact contour for contacting a reaction vessel unit, which protrude laterally in such a way that guides of a rotor can engage behind them and thus fix the collecting device and the reaction vessel unit in the rotor in a rotationally fixed manner.

These projections can, for example, be webs that protrude laterally along the flank side and lie flat on the reaction vessel unit.

However, it is also possible that instead of the webs, only a few laterally protruding individual projections or small feet are formed, which can be gripped behind to guide the rotor.

In a preferred embodiment, a corresponding reaction vessel unit has one or more recesses for receiving the corresponding projections of the collecting device, so that the side of the projections pointing away from the reaction vessel unit is flush with the remaining surface of the reaction vessel unit. With such a configuration of the reaction vessel units, it is possible to arrange the reaction vessel units with and without a collecting device in the rotor, with the reaction vessel unit without a collecting device and the reaction vessel unit with the collecting device being engaged behind by the guide of the rotor with approximately the same small amount of play and thus being fixed in the rotor in a torque-proof manner . Such a combination of collecting device and reaction vessel unit can also be used in corresponding centrifuges which are not designed to accommodate collecting devices. This combination is particularly advantageous in connection with a collecting device having suction means, which in particular does not have a discharge opening and hermetically seals the collecting space within the collecting device from the remaining area of the rotor chamber.

The collecting device and/or the reaction vessel unit is preferably formed from a polymer material. They are produced in particular as an injection molded part.

A discharge device can be provided, which is arranged in a rotor chamber of the centrifuge, in which the rotor rotates, and which is designed to collect liquid discharged from the collecting device. In this case, the collecting device can be designed depending on the type of delivery of the liquid from the collecting device. In particular, the collecting device can be designed to collect liquid which emerges from a discharge opening or spout of the collecting device during centrifugation.

For example, the discharge device can have an annular channel which is open to the rotor chamber and concentric to the axis of rotation and which is opposite a discharge opening of the collecting device. The chute can receive the caught and discharged substances from the catcher without fouling the rotor chamber. In particular, the channel can have an annular opening in which a spout of the collecting device, from which liquid escapes during centrifugation, can be accommodated. Even without a spout, the discharged substances can possibly get into the channel simply because of the speed of the liquid and a suitable arrangement.

The channel of the discharge device can be located opposite the discharge opening of the collecting device in the axial direction. Thus, the channel can accommodate a spout which extends in the axial direction from the catcher and which rotates in a circle when the rotor rotates. The liquid can be absorbed even more cleanly and safely. Since the trough receives the spout axially outside of the end wall of the catcher, liquid can pass from the trough onto the spout but not onto an outer surface of the catcher.

The groove can have an annular opening formed axially towards the rotor chamber, the annular opening having an undercut radially inwards and/or radially outwards. As a result, liquids can be collected even more safely and can flow down the channel freely and undisturbed, where they can be collected and, if necessary, drained or drawn off.

With an outlet device, which is formed at a lower end of the discharge device, liquid can be discharged directly from the collecting device to the outside.

A further aspect of the invention relates to a method for cleaning a reaction vessel unit, which has a plurality of reaction vessels, the reaction vessels each having an opening which lies in a common opening plane, the reaction vessel unit on a rotor of the centrifuge with its openings pointing from an axis of rotation of the rotor is received facing outwards, and the rotor with the reaction vessel unit arranged thereon is rotated in the centrifuge so that a liquid contained in the reaction vessels is spun out. With a collecting device with a collecting plate, which is arranged radially outside of the opening plane of the reaction vessels and rotates together with the reaction vessel unit, the ejected liquid is collected and discharged along the collecting plate. The collecting device and/or the centrifuge is preferably designed according to the description of the above aspects of the invention. The method essentially has the same advantages and effects as the collecting device or centrifuge described above. The reaction vessel unit can be accommodated on the rotor in a manner known per se by form-fitting elements, for example rail-like clamps, into which the reaction vessel unit is pushed. For this purpose, an end wall of the rotor chamber can have a loading window through which the reaction vessel unit can be pushed into and pulled out of the rotor chamber. The use of the collecting device and the execution of the method depend on the type of design and arrangement of the collecting device and can be a loose or fixed attachment of the collecting device to the reaction vessel unit before or after arranging the reaction vessel unit on the rotor, a detachable or non-detachable attachment of the collecting device on the rotor before or (only in the case of a detachable attachment) after the arrangement of the reaction vessel unit on the rotor, an attachment of the collecting device to a rotor shaft of the drive separately or together with the rotor. For example, a collecting device can be provided fixed to the rotor of the centrifuge. In this case, the reaction vessel assembly is simply placed in the centrifuge on the rotor under the catcher plate. In other cases, the catcher may form an assembly with the reaction vessel assembly that is assembled outside of the centrifuge and loaded into and unloaded from the centrifuge together.

The collection device can be cleaned after one or more centrifugation processes. The cleaning can be done by autoclaving and/or by chemical means and/or by irradiation. Cleaning the collecting device is easier and cheaper than cleaning the entire centrifuge or the entire rotor chamber with the rotor. Since the collecting device is provided, cleaning intervals of the centrifuge itself or the rotor chamber can be extended, particularly when the collecting device forms a closed collecting space from which little or no liquid gets into the rotor chamber itself. A catcher provided within the rotor chamber of the centrifuge for collecting discharged liquid from the catcher may be cleaned together with the catcher or separately therefrom by the same or a different method. In a particularly simple manner, the collecting device can be obtained by centrifuging a reaction vessel unit that is filled with a cleaning solution. The collecting device can also be cleaned using the cleaning solution emerging from the collecting device.

A rotor chamber of the centrifuge can be cleaned after a predetermined number of centrifuging processes. The cleaning can be carried out by rinsing with a rinsing solution or by separately cleaning dismantled parts of the centrifuge which delimit the rotor chamber. Examples of suitable cleaning methods are autoclaving, chemical agents (biocides) or irradiation. Since the collecting device is provided, the specified number of centrifuging processes after which cleaning takes place can be greater, ie cleaning intervals of the centrifuge or the rotor chamber can be lengthened. A catcher provided within the rotor chamber for collecting drained liquid from the catcher may be cleaned in the same operation or separately by another method. Here, too, it is possible to clean the rotor chamber by centrifuging a reaction vessel unit that is filled with a cleaning solution. This process is particularly easy to carry out if the collecting device is open at the flanks, because then the cleaning solution can easily get into the rotor chamber. When the catcher is closed, the catcher can be removed from the rotor prior to the cleaning cycle with cleaning solution, allowing the cleaning solution to reach the inner walls of the rotor chamber. If the rotor has two receiving positions for reaction vessel units, but only one of the receiving positions is provided with a collecting device that forms a closed collecting space, this can be placed on the receiving position with the discharge device to clean the reaction vessel units, while the reaction vessel unit can be used to clean the rotor chamber of the cleaning solution on the receiving place without the collecting device is placed. A cleaning solution can be dispensed with to clean the collecting device in the rotor chamber if the rotor or the discharge device is aerodynamically designed in such a way that the collecting device (e.g. a chute described above) is cleaned (blown out) by an air flow generated during rotation.

• 1A eine Zentrifuge in einer Seitenansicht von außen;
• 1B die Zentrifuge von 1A in einer stirnseitigen Ansicht in Blickrichtung eines Pfeils „B“ in 1A;
• 2 einen Innenraum eines Rotorkastens der Zentrifuge von 1A, 1B mit einer Reaktionsgefäßeinheit ohne Auffangvorrichtung in einer stirnseitigen Ansicht bei entfernter Stirnwand;
• 3 den Innenraum des Rotorkastens von 2 mit einer Reaktionsgefäßeinheit und mit einer erfindungsgemäßen Auffangvorrichtung in einer stirnseitigen Schnittansicht entsprechend einer in 1A durch eine Linie „III“ angedeuteten Schnittebene;
• 4A die Zentrifuge in einer Seitenansicht entsprechend 1A mit entfernter Haube;
• 4B die Zentrifuge von 4A in einer stirnseitigen Ansicht in Blickrichtung eines Pfeils „B“ in 4A;
• 4C die Zentrifuge von 4A mit entfernter Haube, wobei ein Rotorkasten und darin befindliche Elemente entlang einer Ebene „C“ in 4B geschnitten sind;
• 4D den Rotorkasten der Zentrifuge aus 4A in einer vergrößerten Ansicht entsprechend einem Ausschnitt „D“ in 4C;
• 4E den Rotorkasten der 4A in einer Seitenansicht geschnitten entlang einer Ebene „E“ in 4B;
• 4F,4G,4H die Zentrifuge von 4A in einer stirnseitigen Ansicht in Blickrichtung eines Pfeils „F“, „G“ und „H“ in 4A;
• 5A den Rotorkasten der Zentrifuge aus 4A in einer perspektivischen Ansicht;
• 5B den Rotorkasten aus 5A in einer perspektivischen Ansicht geschnitten entlang der Ebene „E“ in 4B;
• 6A eine Baugruppe mit Rotorwelle, Rotor, Auffangvorrichtung und Auffangvorrichtung in der Zentrifuge mit darin aufgenommener Reaktionsgefäßeinheit in einer perspektivischen Ansicht;
• 6B die Baugruppe von 6A in einer anderen perspektivischen Ansicht;
• 6C die Baugruppe von 6A geschnitten entlang der Ebene „C“ in 4B;
• 7A eine Baugruppe mit Rotorwelle, Rotor und Auffangvorrichtung in der Zentrifuge mit darin aufgenommener Reaktionsgefäßeinheit in einer perspektivischen Ansicht;
• 7B die Baugruppe von 7A geschnitten entlang der Ebene „C“ in 4B;
• 8 Varianten (a) bis (g) einer Kontur der Auffangplatte mit Reaktionsgefäßeinheit auf einem Rotor im Querschnitt quer bzw. senkrecht zur Rotationsachse;
• 9 Varianten (a) bis (h) einer Kontur der Auffangplatte mit Reaktionsgefäßeinheit auf einem Rotor in einem Axialschnitt entlang der Rotationsachse;
• 10A, 10B eine Auffangvorrichtung und eine Reaktionsgefäßeinheit in einer Draufsicht und in einer Seitenansicht.

Selected embodiments of the present invention are described in detail below with reference to the accompanying drawings. It shows/show:

• 1A a centrifuge in a side view from the outside;
• 1B the centrifuge of 1A in an end view looking in the direction of an arrow "B" in 1A ;
• 2 an interior of a rotor box of the centrifuge of FIG 1A , 1B with a reaction vessel unit without a collecting device in an end view with the end wall removed;
• 3 the interior of the rotor box from 2 with a reaction vessel unit and with a collecting device according to the invention in a front sectional view corresponding to an in 1A sectional plane indicated by a line "III";
• 4A the centrifuge in a side view accordingly 1A with the hood removed;
• 4B the centrifuge of 4A in an end view looking in the direction of an arrow "B" in 4A ;
• 4C the centrifuge of 4A with the hood removed, showing a rotor box and elements therein along a plane "C" in 4B are cut;
• 4D the rotor box of the centrifuge 4A in an enlarged view corresponding to a detail "D" in 4C ;
• 4E the rotor box 4A in a side view sectioned along a plane "E" in 4B ;
• 4F , 4G , 4H the centrifuge of 4A in an end view looking in the direction of an arrow "F", "G" and "H" in 4A ;
• 5A the rotor box of the centrifuge 4A in a perspective view;
• 5B the rotor box 5A in a perspective view sectioned along the plane "E" in 4B ;
• 6A a perspective view of an assembly with rotor shaft, rotor, collecting device and collecting device in the centrifuge with the reaction vessel unit accommodated therein;
• 6B the assembly of 6A in another perspective view;
• 6C the assembly of 6A cut along plane "C" in 4B ;
• 7A a perspective view of an assembly with a rotor shaft, rotor and collecting device in the centrifuge with a reaction vessel unit accommodated therein;
• 7B the assembly of 7A cut along plane "C" in 4B ;
• 8th Variants (a) to (g) of a contour of the collecting plate with a reaction vessel unit on a rotor in a cross-section transverse or perpendicular to the axis of rotation;
• 9 Variants (a) to (h) of a contour of the collecting plate with reaction vessel unit on a rotor in an axial section along the axis of rotation;
• 10A , 10B a collecting device and a reaction vessel unit in a plan view and in a side view.

All graphic representations are to be understood as schematic. Size ratios may be distorted for clarity. Unless otherwise stated, directional and position designations refer to the usual use of the subject matter of the invention.

A centrifuge 1 has a drive box 2 and a rotor box 3 resting on feet 4 ( 1A , 1B ). The drive box 2 houses a drive unit, such as an electric motor (not shown in detail). The drive box 2 has a hood 5 which is fastened to a supporting structure of the rotor box 3 by means of screws 6 . The supporting structure can consist of an end wall 7 as well as a base 27 and a rear wall 28 of the rotor box 3 (see, for example, 5A be formed with screw holes 53 for mounting the hood 5). The hood 5 can have two side walls 13 and a top wall 14, which are designed as individual elements or as a continuous angled sheet metal structure (cf. 2 ). The side walls 13 and the top wall 14 of the hood 5 and the end wall 7, a base 27 and a rear wall 28 of the rotor box 3 define or encompass an interior space of the rotor box 3, which is also referred to as a rotor chamber 29. The end wall 7 has a loading window 8 (cf. 1B ), via which an interior of the rotor box 3 is accessible in order to connect the centrifuge with a reaction vessel unit 21 ( 2 ) to load, as is known per se. The end wall 7 can also be a Achsöff feature 9 ( 1B ), which accommodates a rotor shaft 10 of the centrifuge 1 for rotation about an axis of rotation 11. The axle opening 9 can also be designed as a bearing seat for a bearing 12 for supporting the rotor shaft, but the rotor shaft can also run freely in the axle opening 9 .

The rotor shaft 10 carries a rotor 20 which is connected to the rotor shaft 10 in a torque-proof manner in order to rotate in an interior space of the rotor box 3 ( 2 ). For this purpose, the rotor shaft 10 is connected to an output shaft of the drive unit of the centrifuge 1. Alternatively, it is also conceivable that the rotor shaft 10 is an integral part of the output shaft of the drive unit. The rotor 20 is designed to accommodate at least one reaction vessel unit 21. In the present exemplary embodiment, the rotor 20 can accommodate two reaction vessel units 21, of which only one is shown in the figure. The rotor 20 has a frame 22 which is approximately cuboid and is non-rotatably connected or connectable to the rotor shaft 10 . A receiving space 23 for a reaction vessel unit 21 is formed on each of two axially opposite sides of the frame 22 . In design variants, only a single receiving space 23 or more than two receiving spaces 23 can be provided. The receiving space 23 is delimited by two rail-like brackets 24 which protrude from the frame 22 . A support surface 25 for the reaction vessel unit 21 is formed on the frame 22 itself, while respective mating surfaces 26 are formed on the clamps 24, which are formed parallel to the support surface 25 and spaced from it to fit according to a height of the reaction vessel unit 21. The reaction vessel unit 21 can be placed on the rotor 20 in a manner known per se via the loading window 8 in the front wall 7 or removed from it when the rotor 20 is in a position in which the receiving space 23 is located exactly opposite the loading window 8 . The loading process can be carried out by means of a loading device, as can be seen from the WO 2017/125598 A1 , is known to be carried out automatically. For this purpose, the loading device has an automatically actuatable displacement rod (not shown) for positioning a reaction vessel unit.

The reaction vessel unit 21 is a body with a large number of individual reaction vessels 37 which are arranged next to one another in the reaction vessel unit 21 and each have an opening 38 on one side ( 3 ). The openings 38 lie in a common opening plane 39 and point radially outwards for cleaning purposes. The clamps 24 of the receiving locations 23 are designed in such a way that they only grip the reaction vessel unit 21 at the edge, so that the openings 38 of the individual reaction vessels 37 of the reaction vessel unit 21 are exposed. When the rotor 20 rotates about the axis of rotation 11 at a suitable rotational speed, liquids contained in the reaction vessels 37 of the reaction vessel unit 21 can be thrown radially outward. The liquid ejected from the reaction vessel unit 21 can be caught by the walls of the rotor chamber 29, in particular the insides of the side walls 13 and the top wall 14 of the hood 5 and a top width of the base 27, run down from there and, if necessary, be caught and discharged. as is known per se. The rotational speed for this is a few 100 to a few 1000 rpm.

According to an embodiment of the present invention, a collecting device 30 is provided, which is arranged radially outside of the reaction vessel unit 21 ( 3 ). The collecting device 30 has a collecting plate 31 which is arranged opposite the openings 38 of the reaction vessels 37 . The collecting plate 31 extends beyond the dimensions of the rotor 20 both in the width direction w and in the axial direction (direction of the axis of rotation 11). In modifications it can be sufficient if the collecting plate 31 covers at least the reaction vessel unit 21 or at least all openings 38 of the reaction vessels 37 of the reaction vessel unit 21 . When the rotor 20 rotates at a rotational speed suitable for centrifugation, liquid from the reaction vessels 37 is thrown through the openings 38 by the action of centrifugal force and is caught by the collecting plate 31 . In the area of a central plane 36, which runs at right angles through the opening plane 39 of the reaction vessel unit 21 and along the axis of rotation 11, a radial distance ro of the collecting plate 31 to the axis of rotation 11 is smallest, while the radial distance r in the width direction r to the edge 32 of the collecting device increases towards Correspondingly, a centrifugal acceleration also increases towards the edge 32 of the collecting device 30 , so that the collected liquid is driven along a surface of the collecting plate 31 in the width direction w towards the edge 32 . A flank 33 of the collecting device 30 adjoining the edge 32 of the collecting plate 31 can be open, so that the liquid driven outwards by the centrifugal acceleration is driven further beyond the edge 32 and ejected into the rotor chamber 29 . If the rotor 20 stops in the position in which the reaction vessel unit 21 can be removed from the front wall 7 via the loading window 8, the collecting device 32 prevents liquid dripping from the top wall 14 from getting back into the reaction vessels 37, so that the Reaction vessel unit 21 clean can be taken. As a result, cross-contamination processes can be effectively prevented when centrifuging a plurality of reaction vessel units 21 with different fillings.

If the edge 32 of the collecting plate 31 is arranged laterally offset from the reaction vessel unit 21 on the one hand and downwards on the other hand, i. H. toward the rotor, a drip edge can also be formed, from which liquid can drip down next to the rotor 20 when the rotor 20 is at a standstill.

The edge 32 of the collecting plate 31 can also be drawn down so far that it holds back the liquid ejected from the reaction vessel unit 21 during rotation and this only drips down the side of the rotor 20 when the rotor is at a standstill. As a result, wetting of the inner walls of the rotor chamber 29 can also be significantly reduced.

The collecting device 30 can be formed integrally with the rotor 20 or attached or attachable thereto. The collecting device 30 can in particular be removable from the rotor 20 so that it can be cleaned separately. The collecting device 30 can also be attached to the rotor shaft 10 independently of the rotor 20 (not shown in more detail).

In a further exemplary embodiment, the collecting plate 31 of the collecting device 30 is designed to rise from a front face 41 to an opposite rear face 42 of the collecting device 30 ( 4A until 7B ). This embodiment is a preferred modification of the embodiment of FIG 3 and makes use of its features, unless otherwise described below. The front face 41 is situated on the side of the face wall 7 of the rotor box 3 seen in the axial direction, and the rear face 42 of the collecting device 30 is situated on the side of the rear wall 28 of the rotor box 3 seen in the axial direction. In other words, the collecting plate 31 has a bevel which, in relation to the axis of rotation 11 of the rotor 20 , rises towards the rear face 42 of the collecting device 30 and thus towards the rear wall 28 of the rotor box 3 . An inner side of the collecting plate 31 forms a deflection angle α with the axis of rotation 11 of the rotor 20 or with the opening plane 39 of a reaction vessel unit 21 accommodated on the rotor 20 ( 4A , 4C ). Accordingly, in the centrifuging operation at a rotating speed, liquid trapped on the receiving plate 31 is thrown along the slope (direction of arrow a in 4C ) driven to the rear face 42 of the catcher 30. Two drain openings 43 are formed in the rear end face 42, each of which is followed by a spout 44 protruding from the rear end face 42 in the axial direction.

On the rear wall 28 of the rotor box 3, which is adjacent to the drive box 2, a collecting device 40 is provided. The catcher 40 may be integrally formed with the rear wall 28 or may be manufactured separately and connected to the rear wall 28 . (It should be noted that the capture device is also shown schematically in 2 and 3 is shown, but is not functionally required there.) In the present exemplary embodiment, the collecting device 40 is a ring-shaped or disk-shaped structure which is arranged on an inner side of the rear wall 28 . However, the invention is not limited to this shape, and the collecting device 40 can in principle have any shape that is suitable for collecting and draining the liquid.

An annular groove 45 is formed in the catcher 40 on the side facing the rotor 20, i.e. the inside. The channel 45 has an annular opening 46 pointing in the axial direction towards the rotor chamber 29 . Behind the ring opening 46, the groove 45 widens radially inwards and radially outwards in order to form an inner undercut 47 and an outer undercut 48 with the ring opening 46. At the lowest point, the collecting device 40 has a drainage device 49 which is connected to the channel 45 . The two spouts 44 of the collecting device 30 protrude through the ring opening 46 into the channel 45 . The liquid collected by the collecting device 30 on the collecting plate 31 collects under the effect of centrifugal acceleration at the outer (flank) ends of the rear face 42 of the collecting device 31 in the width direction discharged into the channel 45. The liquid can flow downwards in the channel 45 and be removed from the rotor chamber 29 through the drain pipe 49 .

Since all of the liquid spun out of the reaction vessel unit 21 is collected in the channel 45, the interior of the rotor box 3 (the rotor chamber 29) remains largely unwetted by the liquid. Only mist produced by turbulence can get out of the channel 45 into the rotor chamber 29 and wet its walls.

In a preferred embodiment, the collecting device 31 is designed such that it is flush with the lateral edges of the reaction vessel unit 21 and/or the rotor with flanks 33 or lateral walls, so that an essentially closed space is formed becomes. As a result, the atmosphere within the collecting device 31 is carried along when the rotor rotates and is not or only slightly turbulent. This prevents the formation of aerosols that are distributed in the rotor chamber 29 .

It is only necessary to clean the interior of the rotor box 3 from time to time if the formation of such a contaminated mist cannot be prevented. In principle, the cleaning intervals can be lengthened considerably in comparison with a centrifuging process without the collecting device 30 and collecting device 40 . The collecting plate 31 reliably protects the reaction vessel unit 21 from any contamination by any liquid dripping from the top wall 14 of the hood 5 . Since the collecting device 30 is also closed at the flanks 33, the collecting device 30 forms a closed space with the reaction vessel unit 21, so that any liquid mist that may be present in the rotor chamber 29 cannot settle on a surface of the reaction vessel unit 21 and cause turbulence due to the Rotation in the space between the reaction vessel unit 21 and the receiver plate 31 can be effectively prevented. The reaction vessel unit 21 can therefore be reliably and completely cleaned by centrifugation with the collecting device 30 of this embodiment and protected from any wetting by the centrifugation process or contamination by falling drops.

The invention has been described above with reference to preferred exemplary embodiments. It is understood that numerous modifications are possible within the scope of the invention. The shape of the collecting plate 31 depends on the desired effects. 8th shows schematically several variants 8(a) to 8(g) of a contour of the collecting plate 31 with the reaction vessel unit 21 in a cross section (radial section) perpendicular or radial to the axis of rotation 11. 9 9(a) to 9(h) of a contour of the collecting plate 31 with the reaction vessel unit 21 in an axial section along the axis of rotation 11. It goes without saying that further variants are conceivable. The cross-sectional shapes of 8th and 9 can be combined in any way. They can be designed with open or closed flanks.

The collecting plate 31 can be seen in cross-section perpendicular to the axis of rotation ( 8th ) even ( 8(a) ), with a central kink 80 along the axis of rotation ( 8(b), (e) ), with two lateral kinks along the axis of rotation ( 8(d, g) or convex (c, f), concave when viewed from the outside ( 8(b), (c), (d) ) or convex ( 8(e), (f), (g) ) be trained. As related to 2 described, the centrifugal acceleration in the cross-sectional plane transverse to the axis of rotation 11 always acts in the direction of the larger radius r, therefore liquid collected on the inside of the collecting plate 31 is also 8(a) ) are driven to the flank-side edges 32. This effect can be intensified by a concave design, in which the edges 32 are pulled away (upwards) from the axis of rotation ( 8(b), (c), (d) ), but weakened by a convex configuration in which the edges 32 are drawn (downward) towards the axis of rotation ( 8(b), (c), (d) ). For a convex shape with a central kink 80 ( 8(e) ) the catching plate initially falls off more steeply than a circle 82 around the axis of rotation. Therefore, liquid can collect in the area around the central bend 80 in each case up to a reversal point 83, from which the collecting plate 31 falls flatter than the perimeter 82. In order to avoid this, the shape with two lateral kinks 81, which are arranged beyond the reversal point 83, is preferable, since the liquid is then reliably drained from the central area to the outside ( 8(g) ). For the same reason, it is advantageous if, in the case of the curvature of a collecting plate 31 ( 8(f) ) the radius of curvature of the collecting plate 31 is greater than the radial distance of the collecting plate 31 at the point closest to the axis, i.e. in the area of the central plane 36.

In an axial section along the axis of rotation ( 9 ) the collecting plate 31 can be flat, i.e. at the same distance from the axis of rotation 11 ( 9(a) ), oblique on one side, i.e. rising from a first end face 41 to a second end face 42 ( 9(b)-(d) ), oblique on both sides, i.e. rising towards both end faces 41, 42 ( 9(e)-(g) ) or descending ( 9(h) ) be formed, with the slope in each case straight ( 9(b), (e), (h) ) or arched ( 9(c), (d), (f), (g) ), concave seen from the outside ( 9(d), (e), (f) ) or convex ( 9(c), (g) ) can be formed, and wherein the shapes that are inclined on both sides can have a kink 91 between the end faces 41, 42. Due to the axial slope, which increases towards one or both end faces 41, 42, liquid is diverted due to the centrifugal acceleration along the inside or underside of the collecting plate 31 to the respective end face 41, 42 towards which the slope increases. The flow rate can be slowed down by a convex shape towards the respective front side, accelerated by a concave shape. In the case of axially inclined shapes, it makes sense if the flanks are closed or at least pulled down far enough to oppose an obstacle to the flow transverse to the axis of rotation, so that the liquid is only diverted to the end face(s) to which the inclination rises, where the liquid can be collected without to wet the rotor chamber. In the case of a slant on one side, the structural complexity for collecting the liquid is lower, since a collecting device for the drained liquid only has to be provided on one side. This is preferably provided on a rear wall of the rotor chamber, since the liquid can then be reliably drained away from the end face from which the reaction vessel unit is loaded. In the case of very large amounts of liquid to be drained, a slope on both sides can be advantageous, since the liquid can then be collected more quickly. A double-sided, from the end faces 41, 42 to a cross-section 90 rising Kontor of the collecting plate 31 can concentrate the liquid in a bend 91 at the two flank edges. There, the liquid can be ejected laterally through respective discharge openings. If necessary, a trough-like ring-shaped collecting device can be provided in the rotor chamber in the region of the cross section 90, which collects the liquid thrown out there and drains it downwards.

Other variants are conceivable. For example, the collecting device 30 can have the shape of a trough without further discharge openings. In this variant, it is advantageous if the collecting device 30 is attached to the reaction vessel unit 21 outside of the centrifuge 1 and the reaction vessel unit 21 is loaded into the centrifuge in this way. In this case, the method must be modified so that the rotor stops in the lower position at the end of the centrifugation process, so that the collecting device 30 comes to rest below the reaction vessel unit 21, and the reaction vessel unit 21 with the collecting device 30 and the liquid collected therein is replaced by a Unloading window (not shown) in the end wall 7 is unloaded and separated from the collecting device 30 and the collecting device 30 is then freed from the liquid, cleaned and made available for a further centrifugation process. With such a variant, the rotor chamber remains free of the centrifuged liquid even without a collecting device installed in it. No catcher needs to be provided on the rotor, and cleaning of the rotor chamber and catcher can be made even easier.

It should be noted that the in 2 embodiment shown corresponds to a combination of the cross-sectional shape 8(a) with the axial sectional shape 9(a) with open flanks and in 3A until 7B shown embodiment corresponds to a combination of the cross-sectional shape 8 (a) with the axial section shape 9 (b) with closed flanks.

Another embodiment of a collecting device 30 ( 10A , 10B ) has a collecting plate 31, which is provided with peripheral flanks 33, so that the collecting device 30 is formed approximately trough-shaped. On the free edges of the flanks 33, projections 92 projecting laterally are formed on the collecting device 30 in each case. The projections 92 can also be referred to as feet.

The reaction vessel unit 21, which has a plurality of reaction vessels 37, has a peripheral edge region 93 in which corresponding recesses 94 are provided for receiving the projections 92 ( 10B ). The recess 94, which can also be referred to as positioning recesses 94, is designed in such a way that the projections 92 are received therein in such a way that the upper side of the projections 92 pointing away from the reaction vessel unit 21 is aligned with the upper side of the remaining area of the edge area 93 of the reaction vessel unit 21 are arranged. Such a configuration has the advantage that the reaction vessel unit 21 can be arranged in a rotor 20 with or without a collecting device 30 and the edge region 93 of the reaction vessel unit 21 and, if applicable, the projections or feet 92 of the collecting device 30 are gripped behind by a guide 95 so that the Reaction vessel unit 21 is securely fixed in the rotor 20 in a torque-proof manner with or without a collecting device 30 .

The projections 92 are arranged unevenly on the two opposing flanks 33 . As a result, the projections 92 engage in the recess 94 according to the key/lock principle only when the collecting device 30 is arranged exactly in a predetermined position or arrangement on the reaction vessel unit 21 . Such a configuration of the projections 92 and the recess 94 is particularly advantageous if the collecting device has a discharge opening which, in particular with an inclined collecting plate 31 , serves to discharge the liquid emptied from the reaction vessels 37 .

The projections 92 and the recess 94 thus form a contact contour of the collecting device 30 or a complementary contour of the reaction vessel unit 21, which causes a clear assignment of the collecting device 30 to the reaction vessel unit 21, the combination of reaction vessel unit 21 and collecting device 30 being arranged only in the rotor 20 of the centrifuge can be when the contact contour and the complementary contour are correctly joined together.

It may also be useful, a clear arrangement by means of appropriate contours between tween the reaction vessel unit and the rotor or the centrifuge. As a result, the rotor, the reaction vessel unit and the collecting device are clearly associated with one another.

Providing the contact contour of the collecting device or the complementary contour of the reaction vessel unit ensures that the reaction vessels are correctly covered.

In the in the 10A , 10B shown embodiment, however, no discharge opening is provided, but the collecting device 30 is trough-shaped. A suction device 96 is arranged on the side of the collecting plate 31 pointing towards the reaction vessels 37 . In the present embodiment, the absorbent is a cellulose pad. Such cellulose pads can be detachably arranged in the collecting device 30 and removed and disposed of after use. For this purpose, the cellulose pads can be provided with an adhesive layer. Latching elements for fixing the suction means 96 can also be provided in the collecting device 30 .

In this exemplary embodiment, during use, the collecting device 30 and the reaction vessel unit 21 are held together in the rotor 20 on the one hand and fixed in the rotor 20 on the other hand by means of the guide 95, which is designed as an elongated guide rail.

However, it is also possible within the scope of the invention to provide latching means both on the collecting device and on the reaction vessel unit, so that both are connected to one another in a detachable manner. However, the latching connection should be strong enough to withstand the centrifugal force occurring in the centrifuge.

The collector and reaction vessel assembly are designed for use in a centrifuge. However, they can also be used for manually emptying the reaction vessels of the reaction vessel unit. This applies in particular to the trough-shaped design of the collecting device.

With the collecting device of the present invention, cross-contamination between reaction vessel units can be prevented, depending on the design of the collecting device, wetting of the reaction vessel units by aerosols in the rotor chamber can be reduced or completely avoided, and contamination of the rotor chamber by ejected liquid can also be significantly reduced or completely avoided. The latter can greatly simplify the cleaning of the rotor chamber. If the liquids in the channel 45 of the collecting device 40 are completely taken up and leakage into the rotor chamber is prevented, a closed rotor chamber can possibly be dispensed with. In other words, the end wall 7 and the hood 5, possibly also the base 27 (unless the latter is required for reasons of stability) of the rotor box 3 are omitted. This can greatly simplify the process of loading and unloading the rotor 20.

Reference List

1

centrifuge

2

drive box

3

rotor box

4

Foot

5

Hood

6

screw

7

bulkhead

8th

loading window

9

axle opening

10

rotor shaft

11

axis of rotation

12

camp

13

Side wall

14

top wall

20

rotor

21

reaction vessel unit

22

Frame

23

recording place

24

bracket

25

bearing surface

26

counter surface

27

Base

28

back panel

29

rotor chamber

30

collection device

31

catch plate

32

edge

33

flank

35

edge

36

midplane

37

reaction vessel

38

opening

39

opening level

40

discharge device

41

front (first) face

42

rear (second) face

43

discharge opening

44

grommet

45

gutter

46

ring opening

47

inner undercut

48

outer undercut

49

drain pipe

50

plate

51

Frame

60

module

70

module

80

central kink

81

lateral kink

82

perimeter

83

turning point

84

surface normal

90

center cross-section

91

kink

92

head Start

93

edge area

94

recess

95

guide

96

absorbent

a

discharge direction

right

radius

r0

smallest radius

w

latitude direction

a

deflection angle

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102017113583 A1 [0006]
• EN 1020211240239 [0007]
• WO 2017125598 A1 [0061]

Claims (17)

Collecting device (30) for a reaction vessel unit (21) which has a plurality of reaction vessels (37), the reaction vessels (37) each having an opening (38) which lies in a common opening plane (39), the collecting device (30) having a Collecting plate (31), which is designed in such a way that it can be arranged or is arranged in a centrifuge (1) opposite the openings (38) of the reaction vessels (37), and is designed in such a way that it communicates with the reaction vessel unit (21) during centrifugation. rotates and liquid escaping from the reaction vessels (37) is collected by the collecting plate (31) due to the centrifugal acceleration. Collecting device (30) after claim 1 , wherein the collecting plate (31) can be arranged or is arranged obliquely with respect to the opening plane (39), so that collected liquid due to the centrifugal acceleration in the centrifuge (1) along the obliquely arranged collecting plate (31) in the axial direction of an axis of rotation (11) of a rotor ( 20) of the centrifuge (1). collecting device claim 1 or 2 , wherein it has a suction means which is arranged and configured on the collecting plate in such a way that it can suck up the collected liquid. collecting device claim 3 , wherein the suction means is formed from a porous material, such as a cellulosic layer, and/or an open-cell foam. Collecting device (30) according to one of Claims 1 until 4 , flanks (33) of the collecting device (30) running approximately parallel to the axis of rotation (11) and extending from the collecting plate (31) in the direction of the reaction vessel unit (21) in order to prevent movement of the liquid transversely to the to form the axis of rotation (11). Collecting device (30) after claim 5 , wherein the flanks (33) and end faces (41, 42) of the collecting device (30) are designed to terminate with an edge (35) of the reaction vessel unit (21). Collecting device (30) after claim 2 or claim 2 and one of the claims 3 until 6 At least one discharge opening (43) is formed on an end face (42) towards which the collecting plate (31) rises, which is preferably flush or substantially flush with the inside of the collecting plate (31). Collecting device (30) after claim 7 , wherein the discharge opening (43) has a spout (44) which protrudes beyond the end face (42). Collecting device (30) according to one of the preceding claims, wherein the collecting device (30) is designed with a circumferential contour which is adapted to the shape of the reaction vessel unit (21), so that the collecting device can preferably be fitted in a form-fitting manner and in particular circumferentially in a form-fitting manner. Collecting device (30) according to one of Claims 1 until 9 , wherein the collecting device (30) is designed to be detachably connectable to the reaction vessel unit (21). Collecting device (30) according to one of Claims 1 until 10 , The collecting device (30) on a rotor (20) of a centrifuge (1) being detachably connectable. Collecting device (30) according to one of Claims 1 until 11 , The collecting device (30) being integrated with a rotor (20) of the centrifuge (1). Collecting device (30) according to one of Claims 1 until 12 , wherein the collecting device (30) has a contact contour in order to contact a reaction vessel unit which has a corresponding complementary contour, the contact contour and the complementary contour being designed in such a way that the collecting device can only be arranged in a single position on the reaction vessel unit, so that the combination of reaction vessel assembly and collector can be placed in a centrifuge. Reaction vessel unit (21) which has a plurality of reaction vessels (37), the reaction vessels (37) each having an opening (38) which lies in a common opening plane (39), and the reaction vessel unit having a complementary contour which is shaped in such a way that the reaction vessel unit only in a single position on the particular Claim 13 trained collecting device can be arranged so that the combination of reaction vessel unit and collecting device can be arranged in a centrifuge. reaction vessel unit Claim 14 , wherein the reaction vessel unit has an asymmetrical insertion contour which is adapted to a corresponding receiving contour of a rotor of a centrifuge in a form-fitting manner such that the reaction vessel unit can only be arranged in a single position in the rotor. Collecting device according to one of Claims 1 until 13 wherein the collecting device has projections in the region of a contact contour for contacting a reaction vessel unit, which protrude laterally in such a way that guides of a rotor can engage behind them and thus fix the collecting device and the reaction vessel unit in the rotor in a rotationally fixed manner. Collecting device according to one of Claims 1 until 13 or 16 , wherein the collecting device is formed from a polymer material and is in particular an injection molded part.

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